RETRACTIONS WERE MADE on October 31, 2023
The scaling of Maxwell's equations is due to basic facts of nature described in
Gravity Volume Theory. This is the neo-Maxwell gravitic scaling that uses the most
primitive dimensions: time and length, tau and r, a time constant and the proton radius r.
Maxwell's variables are given in terms of the proton radius and a time constant in 8D.
Magnitudes are revealed and vectors are not shown. Maxwell named four variables:
E ELECTRIC FIELD INTENSITY, Volts per meter
D electric displacement field, Coulomb per square meter
H MAGNETIC FIELD INTENSITY, Ampere per meter
B magnetic flux density, Weber per square meter
gravito-Maxwellian Equations
gravito-Maxwellian Equations
note 1 : D was deleted and is being reconsidered
note 2 : epsilon permittivity is being reconsidered 3/17/2019 acf
r = 0.950000 * 10^-15 meters
tau = 5.131534 * 10^-9 seconds
n is density of particles, n is per cubic meter in Fig 1 only
M is number of proton electron pairs in relative motion.
v1 is 1 meter per second
v is velocity of charge
G = Newton Universal Gravitational Constant
k = Coulomb Constant
tau is calculated by dropping a rock for
1 second and measuring z, height fallen.
tau = NV* 1 second / (zA)
N = number of baryons in Earth
V = proton volume
z = 4.9033 meters on Earth
A = area of Earth at radius R
R = 6,378,000 meters
Gravity Field is Like E field: r related
Forces use relative length : r proton radius and R radius between objects
forcing a small object that has a mass. Mass is area, used in a test object.
Electric force...
f = E * q * N2
Gravity Volume Theory. This is the neo-Maxwell gravitic scaling that uses the most
primitive dimensions: time and length, tau and r, a time constant and the proton radius r.
Maxwell's variables are given in terms of the proton radius and a time constant in 8D.
Magnitudes are revealed and vectors are not shown. Maxwell named four variables:
E ELECTRIC FIELD INTENSITY, Volts per meter
D electric displacement field, Coulomb per square meter
H MAGNETIC FIELD INTENSITY, Ampere per meter
B magnetic flux density, Weber per square meter
gravito-Maxwellian Equations
Fig 1 Retracted E and D
gravito-Maxwellian Equations
note 1 : D was deleted and is being reconsidered
note 2 : epsilon permittivity is being reconsidered 3/17/2019 acf
r = 0.950000 * 10^-15 meters
tau = 5.131534 * 10^-9 seconds
n is density of particles, n is per cubic meter in Fig 1 only
M is number of proton electron pairs in relative motion.
v1 is 1 meter per second
v is velocity of charge
G = Newton Universal Gravitational Constant
k = Coulomb Constant
tau is calculated by dropping a rock for
1 second and measuring z, height fallen.
tau = NV* 1 second / (zA)
N = number of baryons in Earth
V = proton volume
z = 4.9033 meters on Earth
A = area of Earth at radius R
R = 6,378,000 meters
Gravity Field is Like E field: r related
Forces use relative length : r proton radius and R radius between objects
Force
from the Particulate Relativity of Gravity. Particle
volume causes gravity, particle area responds to that liquid-like flow. Mass
is proportional to an area of something about a particle. Force
magnitude is set by r cubed over R squared. That is representing a liquid-like space for the gravity volume theory.
Newton’s
formula is replaced:
F = -nmNV / (2 p t R^2 second)
n =
number of baryons in the test matter
m =
mass of proton
N =
number of baryons in planet
V =
proton volume = 4/3 p r^3
r = proton radius
0.95fm
t = 5.1315ns Constant
for conservation of continuum, from p
R
is planet radius
second
is from a 1 second drop test
M1 = Nm planet mass
V1 = NV baryon volumes in planet
M2 = nm
V2 = NV
Newton’s
universal gravitational constant has factors:
G =
-V / (2 p t m second)
The
momentum of free space per baryon is p = 7.02 * 10^-37 m^3 / sec
Np =
NV / t = Az / (1 second)
g = -NV / (2 p t R^2 second) = acceleration of gravity
Curvature of space is a velocity allocation of continuum
Curvature of space is a velocity allocation of continuum
S = r R V / (3 m t) = Speed of Space as a liquid
r = mass density, kg /
m^3
The point is that a volume of neutrons and protons for a big object isforcing a small object that has a mass. Mass is area, used in a test object.
Electric force...
f = E * q * N2
Fig 2
Figure 2: retracted except E = Electric field intensity
In Figure 2, N is number of baryons in a planet. q is a charge.
M is number of pairs of proton and electron involved.
v1 is 1 meter per second. v is velocity of charge.
(p-e) = number of protons minus electrons in object with electric field E
E has q charge in the denominator, so force is N2*q*E
where N2 is number of charges in object 2 and (p-e) is number of charges in object 1.
This can be written equivalently as:
E = 255 kilogram meter per second^2 * (r^2 / (q * R^2))
F = N2 * 255 kilogram meter per second^2 * (r^2 / (R^2))
The r^2 is there to model the bond from a proton to an electron using two space dimensions. That is a spline or membrane shape. The two space like dimensions have a time-like counter-flowing dimension. So the r^2 is for a membrane fluid and the r^3 is for the liquid fluid.
Compare that to gravity as a function of R.
g = -(2N / (3 tau second)) * (r^3 / R^2)
Highlight : gravity is from r cubed over R squared but
electric force is from r squared over R squared! This is how reality is
modelled: electron force on a proton is a deterministic 2D membrane, but
gravity is an unpaired 3D situation. So the radius of the proton for gravity
is cubed to cause gravity and r is squared as a mass m. So no direct comparison from
electric to gravitic forces is simply r squared versus r cubed.
The proton radius r is used in two different ways for the two forces.
3D for gravity but 2D for electricity. Like comparing a liquid with
a conveyor belt. An ocean compared to an anchor chain. The little chain
is stronger than the ocean, usually. This is a geometric comparison, then a conversion to
using r in algebraic geometry is attempted for 8 dimensions.
acf 3/15/19
(replaces Coulomb equation factor Force – qE)
Figure 2: retracted except for g = Gravitational acceleration
(Replaces Newton’s Force factor in Force = mg), and except for E, r, and tau.
In Figure 2, N is number of baryons in a planet. q is a charge.
M is number of pairs of proton and electron involved.
v1 is 1 meter per second. v is velocity of charge.
(p-e) = number of protons minus electrons in object with electric field E
E has q charge in the denominator, so force is N2*q*E
where N2 is number of charges in object 2 and (p-e) is number of charges in object 1.
This can be written equivalently as:
E = 255 kilogram meter per second^2 * (r^2 / (q * R^2))
F = N2 * 255 kilogram meter per second^2 * (r^2 / (R^2))
The r^2 is there to model the bond from a proton to an electron using two space dimensions. That is a spline or membrane shape. The two space like dimensions have a time-like counter-flowing dimension. So the r^2 is for a membrane fluid and the r^3 is for the liquid fluid.
Compare that to gravity as a function of R.
g = -(2N / (3 tau second)) * (r^3 / R^2)
electric force is from r squared over R squared! This is how reality is
modelled: electron force on a proton is a deterministic 2D membrane, but
gravity is an unpaired 3D situation. So the radius of the proton for gravity
is cubed to cause gravity and r is squared as a mass m. So no direct comparison from
electric to gravitic forces is simply r squared versus r cubed.
The proton radius r is used in two different ways for the two forces.
3D for gravity but 2D for electricity. Like comparing a liquid with
a conveyor belt. An ocean compared to an anchor chain. The little chain
is stronger than the ocean, usually. This is a geometric comparison, then a conversion to
using r in algebraic geometry is attempted for 8 dimensions.
acf 3/15/19
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